mass spectrometry: forming ions, to identifying proteins ... · mass spectrometry: forming ions, to...
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Mass spectrometry: forming ions,Mass spectrometry: forming ions,to identifying proteins and theirto identifying proteins and their
modificationsmodifications
Stephen Barnes, PhD
4-7117
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Introduction to massIntroduction to massspectrometryspectrometry
• Class 1 - Biology and mass spectrometry– Why is mass spectrometry so important?
– Short history of mass spectrometry
– Ionization and measurement of ions
• Class 2 - The mass spectrum– What is a mass spectrum?
– Interpreting ESI and MALDI-TOF spectra
– Combining peptide separation with mass spectrometry
– MALDI mass fingerprinting
– Tandem mass spectrometry and peptide sequencing
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Goals of research on proteins
• To know which proteins are expressed ineach cell, preferably one cell at a time
• Major analytical challenges– Sensitivity - no PCR reaction for proteins– Larger number of protein forms than open
reading frames– Huge dynamic range (109)– Spatial and time-dependent issues
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Changes at the protein level
• To know how proteins are modified, informationthat cannot necessarily be deduced from thenucleotide sequence of individual genes.
• Modification may take the form of– specific deletions (leader sequences),
– enzymatically induced additions and subsequentdeletions (e.g., phosphorylation and glycosylation),
– intended chemical changes (e.g., alkylation of sulfhydrylgroups),
– and unwanted chemical changes (e.g., oxidation ofsulfhydryl groups, nitration, etc.).
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Proteins once you have them
Protein structure and protein-proteininteraction– to determine how proteins assemble in
solution
– how they interact with each other
– Transient structural and chemical changes thatare part of enzyme catalysis, receptoractivation and transporters
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So, what So, what youyou need to know need to knowabout mass specabout mass spec
• Substances have to be ionized to bedetected.
• The net charge can be either positive ornegative.
• The mass-to-charge ratio of an ion (m/z) isthe most important parameter.
• The mass spectrometer is a selectivedetector (based on mass differences), butall the substances that are present in asample and can be ionized are measured.
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Important things to knowImportant things to know
• Polyionic buffer salts, particularlyphosphate, interfere with ion formation inthe electrospray ionization interface.
• Matrix-assisted laser desorption ionizationtime-of-flight mass spectrometry (MALDI-TOF) is very tolerant of the biomedicalscientist.
• The mass spectrometer is always right.
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Where did mass spectrometryWhere did mass spectrometrycome from?come from?
1803 Dalton proposes atomic theory of matter1886 Discovery of “canal rays” by Goldstein1905 J.J. Thompson introduces the use of low pressure1919 Francis Aston establishes isotopes of neon (20/22)1931 Aston discovers U-235/U238 isotopes1937 Aston notes the mass defect of elements up to
fluorine - e = mc2
1938 Hahn/Strassman observe uranium fission1940 Nier begins isolation of U235 by mass spec1943 Army takes over - Manhattan project (Lawrence)
Postwar - modern mass spectrometry begins1952 First meeting of the ASMS
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Biomedical Mass SpectrometryBiomedical Mass Spectrometry
Early work in mass specconcentrated on isotopes and isotoperatios (2H/1H, 13C/12C and 15N/14N)
DavidRittenberg
Rittenberg and Schoenheimerestablished many of the pathways ofmetabolism using these isotopes
The combination of gaschromatography and massspectrometry was good for smallmolecules
BUT what about proteins, peptides andother heat labile molecules?
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OutlineOutline
• Interfaces and ion sources– Heated nebulizer atmospheric pressure chemical
ionization– Electrospray ionization (ESI)
» conventional and nanospray– Matrix assisted laser desorption ionization
• Types of MS analyzers– Magnetic sector– Quadrupole– Time-of-flight– Ion trap/FT-ICR– Hybrid
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Interfaces and ion sources
• Direct insertion probe - probe heated• GC-MS (Ryhage, Biemann) volatile derivatives,
thermal decomposition, not good for eitherpeptides or proteins
• Field desorption - on carbon fibers• Sputtering - glycerol matrix for fast atom
bombardment (FAB)Matrix-assisted laser desorption
• Spraying- Thermospray ionization- Heated nebulizer atmospheric pressure
chemical ionization- Electrospray ionization
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HN-APCI interfaceHN-APCI interface
Vacuum
MassAnalyzer
N2 curtain gas
From HPLC column(1 ml/min)
Quartz tube at500oC
Atmosphericpressure
Corona discharge
Ionized airand solvent
+ + + +
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Electrospray ionizationElectrospray ionization
Peptides and proteins can be transferred from solution into the gasphase without degradation by forming a nebulized spray of droplets (aTaylor cone) which are subject to rapid evaporation by warm nitrogen“curtain” gas. Typically, the nebulizing solution contains 30%acetonitrile which lowers the surface tension (and decreases dropletsize) and facilitates the evaporation. The solutes are ejected from thesurface of the droplet probably by coulombic repulsion. This occurs atatmospheric pressure.
The flow rates that are suitable for ESI interfaces vary from 10 nl/min upto 1 ml/min (latter requires turbo heating). Samples can be introducedby flow injection (no chromatography) or following chromatographicseparation.
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Electrospray Ionization (ESI)Electrospray Ionization (ESI)
VacuumAtmospheric pressure
MassAnalyzer
N2 curtain gas
+HV
nebulizinggas
sample solution
++ +
+ +
+ +
++
+++
++
++
[M + nH]n+
++
1. Solvent evaporation2. Coulombic repulsion
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NanoElectrosprayNanoElectrospray
5 µm
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MALDI generation of ionsMALDI generation of ions
Sample mixed with a UV-absorbing matrix and isallowed to co-crystallize on the metal target.
Laser pulse (337 nm)
Peptide/protein deposited on crystal surface
[M+H]+
[M-H]-
matrix ions
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Matrices for MALDI analysisMatrices for MALDI analysisPeptides/proteins- 3,5-dimethoxy-4-hydroxycinnamic acid (sinapinic acid)- α-cyano-4-hydroxycinnamic acid (CHCA)- 2,5-dihydroxybenzoic acid (DHB)- 2-(4-hydroxyphenylazo)-benzoic acid (HABA)
Oligonucleotides- 2-aminobenzoic acid- 3-hydroxypicolinic acid (3-HPA)- 2,4,6-trihydroxyacetophenone (THAP)
The choice of matrix depends greatly on the solute to beanalyzed.
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Matrices for MALDI analysis
OH
COOH
CN
OH
COOH
MeO OMe
CHCA Sinapinic acid
COOH
OH
HO
DHB
COOH
N N
OH
HABA
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Magnetic sector analyzer
Generated ions are accelerated and are passed around a curvedtrack (the sector) leading to a detector. By increasing the magneticfield applied to the ions, heavier ions with higher momentum canbe induced to follow the curved track. A mass spectrum isobtained by applying a magnetic field gradient. Scanning issomewhat slower than in a quadrupole analyzer due to “magneticreluctance”.
106 massresolution
Ion source
magnet
Acceleratingplates
slit
Detector slit
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Quadrupole analyzerQuadrupole analyzer
Generated ions are accelerated electrically (5-15V) and passed along thelong central axis of four rods arranged symmetrically. By applyingcombined DC and oscillating RF potentials, the ions drift along irregularflight paths along the rod axis. The DC/RF ratio is held constant and theabsolute values of DC and RF are varied. Only ions with a particular m/zvalue have stable trajectories for a given value of DC and RF. If DC is set to0, then all ions have stable trajectories. A scan can be accomplished over aperiod of 10-1000 msec.
Mass resolution 2 x 10Mass resolution 2 x 1033
Tolerant of relatively highTolerant of relatively highpressure (10pressure (10-4-4 torrtorr))
Upper limit for Upper limit for m/zm/z is is3,000-4,0003,000-4,000
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Elements of a quadrupole analyzerElements of a quadrupole analyzer
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Time-of-flight (TOF) analyzerTime-of-flight (TOF) analyzer
Generated ions are accelerated so that they have equal kinetic energy.They are allowed to “drift” down a 1 - 1.5 meter tube before striking aphotomultiplier detector. The “time of flight” (t) depends on the mass ofthe ion (m), where t = (m/2eV)1/2.D
V is the applied potential and D is the flight tube distance. For a giveninstrument, the flight time varies as the square root of the mass of the ion.
Resolution 2 x 10Resolution 2 x 1044
No upper limit of massNo upper limit of mass
Scan times ~ 1 Scan times ~ 1 µµsecsec, good, goodfor LC-MSMSfor LC-MSMS
Oscilloscope totime ion arrival(1 µsec)
Source
Acceleratingpulse
Linear flight tube (1.0 - 1.5 m)
Oscilloscopeto time ion arrival
ReflectronEffective flight tube (3.0 m)
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Matrix-Assisted LaserDesorption Ionization (MALDI)
Flight tube and drift region tomeasure the time-of-flight (TOF)
Accelerating pulse
Short laserpulse
detector
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Post-source decay experiments in aTOF-mass spectrometer
Daughter fragment ions formed in the drift region are separated bythe reflector. Suitable resolution only occurs over a limited rangeof m/z values. This can be overcome by recording individualspectra over a wide range of voltage settings (10-12) for thereflector. Alternatively, a curved applied voltage can be used toobtain the daughter ion spectrum in a single experiment.
Acceleratingpulse
Reflectron
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Ion Traps
The ion trap is an energy well - ions with sufficient energy to enter thetrap are retained by an energy barrier on the exit side of the trap. Theadvantage of the ion trap is that it accumulates selected ions prior to theiranalysis giving it high initial sensitivity (detection limit of approx. 20fmol). Ions are fragmented by collision with helium gas and theirdaughter ions analyzed within the trap. Selected daughter ions canundergo further fragmentation, thus allowing MSn. This is important forstructural experiments such as in peptide sequencing. The ion trap has ahigh efficiency of transfer of fragment ions to the next stage offragmentation (unlike the triple quadrupole instrument).
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Expanded view of ion trap
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Ion trap and FT-ICR MSIon trap and FT-ICR MS
A range of rf components are used to excite a sample. The ions clouds theninduce an image current at two or more detection electrodes. The resultingsignal when subjected to FT analysis yields an extremely precise measure ofion cyclotron frequencies, and hence m/z values, and molecular weights. Thesensitivity is substantially enhanced and a 1 to 106 mass resolution can beachieved using a 9.4 tesla magnet.
By placing the ion trap within asuperconducting magnet, the trapped ionsundergo cyclotron gyration and areradially confined. The frequency of thecyclotron radiation is inverselyproportional to the m/z ratio for an ion anddirectly proportional to the magnetic field.If an ion is excited at its natural cyclotronfrequency, it moves to a higher energylevel.
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ThermoFinnigan ThermoFinnigan LTQ-FTLTQ-FT
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Penning Trap (ICR cell)Penning Trap (ICR cell)
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magnetic field
Penning Trap (ICR cell)Penning Trap (ICR cell)
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Once we make an ion, we moveit into the center of the Magnet.Then, we trap it before it can escape.
ION+
ION+
ION+
ION+
ION+
ION+
ION+
ION+
ION+
Electrostatic Barrier
We slam the “Gate” shut before the ion escapes
ION+
Ion is now trapped in the magnet.
Ion sees barrierand is turned back
Moving and Trapping Ions
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B q Bm=ω
Once the ion is trapped,the magnet bends it intoa circular path.
We MEASURE the frequency
We know theMagnetic Field
So we can calculate the mass of the ion
m
“Light” Ions have a High frequency
“Heavy” Ions have a Low frequency
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Two of the sides of the cylinder that make upthe trap are excitation plates.
The other two sides of the cylinder detection plates.
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DifferentialAmplifier
Time (ms)8007006005004003002001000
0.050.040.030.020.010
-0.01-0.02
-0.03-0.04-0.05
Time-Domain Transient
Image Current
As the spiraling ion gets neara detect plate, it induces a current that is detected by the instrument.
The signal is recorded fora period of time and then displayed by the software
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m(e-) = 0.00054 Da So:
0.000452 ± 0.000005 Da(S2H8 vs. N4O)
700500300
2+ Charge StateIsolated
RVMRGMR vs. RSHRGHR (MW ≈ 904 Da)
455454453
* Monoisotopic Mass
High Resolution by FT-ICR MSHigh Resolution by FT-ICR MS
= 3,300,000Δmm
m (Da)906.488 906.491 906.494
S Barnes-UAB 1/25/05Chalmers, M.J., et al. (2004) Proteomics, 4, 970-981
m/z1100700500 1300 1500900
*
*
*
#
#
#
820 830 840
# = calibrant ions*= phosphopeptide ions
*
43 PKA peptide ions |0.7| ppm
Protein kinase AProtein kinase A9.4 T Passively Shielded Magnet9.4 T Passively Shielded Magnet
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Which FTMS Performance Factors Increase With Increasing Field?
•• Resolution (B)Resolution (B)•• Acquisition Speed (1/B)Acquisition Speed (1/B)•• Maximum Ion Kinetic Energy (BMaximum Ion Kinetic Energy (B22))•• Radius for a given kinetic energy (1/BRadius for a given kinetic energy (1/B22))•• Upper mass limit (BUpper mass limit (B22))•• Maximum ion trapping duration (BMaximum ion trapping duration (B22))•• Maximum number of trapped ions (BMaximum number of trapped ions (B22))•• Quadrupolar axialization Quadrupolar axialization efficiency (Befficiency (B22))•• Peak Coalescence (BPeak Coalescence (B22))
Advantages of High Field FTMS
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Comparison of massspectrometers performances
Instrument Mass Mass Sensitivityresolution accuracy
Quadrupole 1 x 103 0.1 Da* 0.5-1.0 pmolDE-MALDI 2 x 104 20 ppm 1-10 fmol peptide
1-5 pmol proteinIon trap 1 x 103 0.1 Da* 10-20 fmolFT-ICR 1 x 106 <1 ppm 20 amole
*depends on the mass window being used
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B q Bm=ω
We measure the frequency
m
“Light” Ions have a High frequency
“Heavy” Ions have a Low frequency
The Lure of The Increased B
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q Bm=ω
While many performance factors increase with
B,
NEVER FORGET for FT-ICR MS
We MEASURE the frequency
MEASURE = Making Ions + Moving Ions
+ Trapping Ions + Detecting Ions
The Lure of The Increased B
B only affects Detecting Ions
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Another hybrid Instrument - Another hybrid Instrument - QtofQtof(hybrid quadrupole-orthogonal time-of-flight)(hybrid quadrupole-orthogonal time-of-flight)
A limitation of the magnetic sector and quadrupole analyzers is thatonly one ion is measured at a time. Thus while analyzing ions over amass range of m/z 1-1000 at unit mass resolution, at any one m/zvalue all the ions at other ions are ignored. This results indiscarding 99.9% of the available information.
For the Qtof, the fragment ions are accelerated orthogonally and allof them are detected by the TOF analyzer.
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Q1 Q2 Q3 Detector
-++--
-- --- -- -
Collision gasN2
GasSample solution
5 KV
Triple quad versus Q-Triple quad versus Q-tof tof and sensitivityand sensitivity
The quadrupole analyzer (Q3) is slowand insensitive - it’s a filter - thusthrows away large amounts of data
Q1 Q2
Collision gas
Electrostaticreflector
TOF detector
TOF detector collects all ions generatedand yields fmol rather than pmol sensitivity
Also gives far greater mass accuracy -from 1000 ppm on the triple quad to <20ppm on the Q-tof
Crucially important for automatedinterpretation of MS-MS spectra to yieldamino acid sequence
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Other hybrid instruments
• MALDI-FT-ICR– Generates singly charged ions
• MALDI-quadrupole trap– High sensitivity and high throughput
• MALDI-TOF-TOF– 200-1000 Hz laser leads to highest rate of MS
analysis (3,000-4,000 spectra/hr)
– Also can record novel MS-MS spectra (500/hr)
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TOF-TOF - high speed MSMSTOF-TOF - high speed MSMS
iongeneration
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PPurdue urdue RRare are IIsotopesotopeMeMeasurement Labasurement Lab
Accelerator mass spectrometry for rareisotopes, 10Be, 14C, 26Al, 36Cl, 41Ca, 129I
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Accelerator in PRIME LabAccelerator in PRIME Lab
Dr. DavidElmore next to10 MVaccelerator
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Inside Accelerator in PRIME LabInside Accelerator in PRIME Lab
If an animal is given 50nCi of a 14C-labeledcompound and 0.01% isabsorbed and reachesthe brain, then 20 mg oftissue is sufficient toprovide enough signalto give a 1000:1 signal-to-noise ratio
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Congratulations to theCongratulations to theNobel Laureates - 2002Nobel Laureates - 2002
"for the development of methods for identification andstructure analyses of biological macromolecules"and"for their development of soft desorption ionisation methodsfor mass spectrometric analyses of biologicalmacromolecules"
John Fenn Koichi Tanaka